|Publication number||US7614444 B2|
|Application number||US 10/842,053|
|Publication date||Nov 10, 2009|
|Filing date||May 7, 2004|
|Priority date||Jan 8, 2002|
|Also published as||US20050000804|
|Publication number||10842053, 842053, US 7614444 B2, US 7614444B2, US-B2-7614444, US7614444 B2, US7614444B2|
|Inventors||Kevin R. Oldenburg|
|Original Assignee||Oldenburg Kevin R|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (49), Non-Patent Citations (14), Classifications (12), Legal Events (3)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This application is a continuation-in-part of U.S. patent application Ser. No. 10/041,703 entitled Rapid Thermal Cycling Device filed Jan. 8, 2002, and U.S. patent application Ser. No. 10/356,687 filed Jan. 31, 2003. The patent applications which are listed in the preceding sentence, including the specifications, figures and claims, are hereby incorporated by reference in their entirety as if fully set forth herein.
The invention of the present application addresses an apparatus and method for purifying ions in a liquid sample, particularly amplified DNA in the wells of a well plate.
Nucleic acid amplification is typically performed by PCR or Cycle Sequencing of DNA in the wells of a well plate by thermal cycling reactions in the presence of a thermostable DNA polymerase such as Taq Polymerase. Well plates containing wells for 96, 384 and 1536 liquid samples currently are available. The solution in which the amplification occurs typically contains many different components including but not limited to, a buffer, nucleotide triphosphates, magnesium chloride, potassium chloride, dithiothreotol, DNA, oligonucleotides, and the DNA polymerase (e.g. Taq). Once the amplification process of the DNA is complete, the reaction solution contains not only the components listed above but reaction byproducts as well. The amplified nucleic acid must then be purified (segregated) from this mixture before additional steps can be performed. There are a number of methods by which DNA can be purified including size exclusion chromatography, gel electrophoresis, and ion exchange chromatography. Other typical methods to purify the DNA all are modifications of the above three methods. All of the currently available methods to purify the DNA products from solution require multiple additional steps and transfer of the product solution from the original reaction container into at least one additional container. It would be beneficial to be able to perform both nucleic acid amplification and purification in the same well of a well plate serially and without further additions to the well.
As used herein, the term “liquid” refers to pure liquids, as well as liquids containing particulate matter (especially biological material containing for example, proteins, DNA, or cells) and solvents containing solute.
In ion exchange chromatography, molecules of one charge (either positive or negative) are attracted to molecules of the opposite charge that are immobilized onto a solid support, usually a glass particle or insoluble organic support. The insoluble support material is then serial “washed” with solutions containing higher and higher concentrations of a specific salt (typically sodium chloride). As the salt concentration increases, the ions in the salt solution “compete” for the ion binding sites on the solid support with the result that at low salt concentrations, molecules with low net charge are competed from (released from) the solid support while molecules with higher net charges remain bound to the solid support.
Nucleic Acids, including Deoxyribonucleic Acid (DNA) and Ribonucleic Acid (RNA), are polymeric anions. As such, they will be attracted by insoluble supports that contain a positive charge (cathodes) and repelled by insoluble supports that contain a negative charge (anodes). Nucleic Acids have been successfully purified from heterogeneous solutions by ion exchange chromatography using various types of insoluble support materials. Typically, this is done through the addition of an ion exchange material into the solution containing the nucleic acid and manipulation of the ionic strength of the solution through the addition of small inorganic ions to allow binding of the nucleic acid to the insoluble support. Once binding of the nucleic acid to the insoluble support has occurred, the solution, and hence the “impurities”, are removed from the soluble support by sequential “washing” of the support. By manipulating the ionic strength of the wash solution, some means of control over the size (length) of the nucleic acid polymer that remains attached to the support can be achieved. The ions in the wash solution compete for binding to the surface charge on the insoluble support with the nucleic acid and hence, the degree of nucleic acid binding can be crudely regulated by changing the concentration of ion in the wash solution. At a relatively low ionic strength (e.g. Distilled water) nucleic acid binding to the insoluble support is nearly independent of size. As the ionic strength of the wash solution increases, the shorter length nucleic acid polymers will elute from the support first, followed by longer polymers as the ionic strength of the wash solution increases.
One of the major problems with the current methods and devices for purification by ionic interaction is that the support materials have a fixed surface charge that cannot be changed. The support materials are usually described in terms of “weak,” “moderate,” or strong anion/cation exchange resins. Each of these “resins” is actually a different material with different physical properties. In order to change the surface charge, different materials are used as the support, or counter ions are used to effectively mask the charge.
Copending U.S. patent application Ser. No. 10/041,703 filed Jan. 8, 2002 and U.S. patent application Ser. 10/356,687 filed Jan. 31, 2003 teach generally the use of a lid for a well plate, for example a well plate having 1536 wells with each well having a volume of 6 μl. The lid has pins depending from the lid for insertion into the wells of a well plate. The pins extend from the upper side of the lid through the lid and into the wells of the well plate. The pins either contact the liquid samples in the wells or are in close physical proximity to the liquid sample without physically contacting the liquid sample. Heat may be supplied to or removed from the upper end of a pin to effect thermal cycling of the liquid sample. Sonic energy may be applied to the upper end of the pin to effect sonication (mechanical shearing) of the sample. An electrical charge may be applied to the upper end of the pin to segregate ions in the liquid sample.
The segregation of a material from a liquid sample in a well of a well plate by application of an electrical charge is referred to in this application as “electrical charge segregation.” As used in this application, the term “pin” means any elongated member. As used in this application, a lid having pins depending from the lid, the pins being adapted to be inserted into the wells of a well plate, is referred to as a “pinned lid.”
The present Invention provides for an improvement in electrical charge segregation of ions having different electrical charges in liquid samples contained in the wells of a well plate. A well plate is provided with a pinned lid. Each pin is a first electrode and is composed of, coated with, or includes on its surface a material that is capable of being electrically charged; that is, of containing a net electrical charge on its surface. An electrical charge, for example a positive electrical charge, is applied to a pin. In the improvement of the Invention, a second electrode is provided for each well of the well plate. To form the second electrode, each well of the well plate is composed of, coated with, or includes on its surface a material that is capable of being electrically charged. Alternatively, the second electrode is separate from the well, such as a second pin. Both the first and second electrodes are in contact with the liquid sample. Different electrical potentials are applied to the first and second electrodes.
Applying a difference in electrical potential between the first and second electrodes speeds the process of electrical charge segregation. Where a positive charge is applied to the pin, rendering the pin an anode, negatively charged ions (anions) in the liquid sample, such as the negatively-charged ions of amplified DNA resulting from PCR or Cycle Sequencing, will be attracted to and bound to the positively-charged pins. Positively charged ions (cations) in the liquid sample, such as the undesirable by-products of the amplification process, are repelled from the anode and are attracted to and bound to the negatively-charged second electrode (the cathode).
By varying the electrical potential between the cathode and the anode, molecules of differing net charge can be isolated. For example, a high net positive charge initially may be imparted to the pin (cathode) and a high net negative charge may be imparted to the second electrode (anode), resulting in a high electrical potential difference between the pin and second electrode. The high potential causes a majority of negatively-bound ions in the liquid sample to be attracted to and bound to the pin. The pin can then be removed from the liquid sample and placed into a second solution (water, buffer, etc.) and the net positive charge on the pin decreased. The result will be that molecules with a low net negative charge will be released into the second solution. This process can be repeated as necessary in order to segregate the desired molecules.
The present Invention also is an apparatus and method for selectively applying any of the steps of thermal cycling, sonication or electrical charge segregation in any sequence to a liquid sample contained in a well of a well plate.
The accompanying drawings, which are incorporated in and form a part of the specification, illustrate the embodiments of the present invention and, together with the description, serve to explain the principles of the invention.
In describing an embodiment of the invention, specific terminology will be selected for the sake of clarity. However, the invention is not intended to be limited to the specific terms so selected, and it is to be understood that each specific term includes all technical equivalents that operate in a similar manner to accomplish a similar purpose.
A. The Pinned Lid and Well Plate.
As shown by
A gasket 26 may be provided to seal the lid 10 against the wells 6 of the well plate 2, inhibiting evaporation of the liquid sample 4 during repeated heating and cooling of the sample 4 during thermal cycling. The gasket 26 is composed of a resilient material, such as silicone rubber. The gasket 26 may appear as a thin layer of resilient material applied to the lower side 28 of the lid 10. The gasket 26 also is useful in preventing microparticulate drops of liquid sample 4 from moving from one well 6 to an adjacent well 6 during sonication. The degree of sealing of the wells 6 required may vary with the application. Depending on the application, the lid 10 may be provided with a gasket 26 under the entire lid 10, a perimeter gasket 26 only, or no gasket 26 at all.
The upper end 16 of each pin 14 is supported by a resilient layer 30 located on the upper side 32 of the lid 10. The resilient layer 30 is composed of silicone rubber or any suitable resilient material. The pin 14 is able to ‘float’ on the resilient layer 30; namely, to move in the direction normal to the plane of the upper side 32 of the lid 10 in response to pressure applied to the pin 14 by, say, an electrical power supply 34, heating and cooling device 36 or sonic horn 38. Because each pin 14 is able to ‘float,’ minor differences in the height of the pins 14 above the upper side 32 of the lid 10 may be overcome by elastic deformation of the resilient layer 30 so that each pin 14 will contact the power supply 34, heating and cooling device 36 or sonic horn 38.
As shown by
The plurality of holes 20 and the number and location of pins 14 match the number and location of wells 6 in the well plate 2 for which the lid 10 will be used. For well plates 2 having 96 wells 6, the pattern of holes 20 and pins 14 is a regular array of 8×12 holes 20 and pins 14. For well plates 2 having 384 wells 6, the pattern of holes 20 and pins 14 is an array of 16×24 holes 20 and pins 14. For well plates 2 having 1536 wells 6, the pattern of holes 20 and pins 6 is an array of 32×48 holes 20 and pins 6.
B. Charge Segregation under the Co-Pending Applications.
As shown by co-pending U.S. patent application Ser, No. 10/041,703 filed Jan. 8, 2002 and U.S. patent application No. 10/356,687 filed Jan. 31, 2003, both of which are incorporated by reference herein, the pinned lid 10 may be used to purify material in a liquid sample 4 in a well 6 of a well plate 2. A positive or negative electrical charge may be placed on the surface of the pins 14 in a pinned lid 10. The electrical charge may be generated or transmitted by a conventional power supply 34, which may be a conventional DC power source or may be a conventional source of electrostatic charge. If a positive charge is applied to the pins 14 then the pins 14 attract negatively charged molecules in the liquid sample 4 in which the pins 14 are placed. The more negatively charged the molecule, the higher the binding affinity of the negatively charged molecule to the positively charged pin 14. The lid 10 and the pins 14 with negatively charged molecules bound to the pins 14 may then be removed from the original liquid sample 4 and placed in a new liquid sample 4 and the electrical charge on the pin 14 can be changed, thereby transfusing the molecules to the new liquid sample 4. In this way, negatively charged molecules can be removed from the original liquid sample 4 resulting in a purified liquid sample 4. The pin 14 initially may be given a negative charge and thus be used to purify positively charged molecules from the initial liquid sample 4.
A primary use of electrical charge segregation is purification of genetic materials after a nucleic acid amplification event. After completion of the step of thermal cycling of a suitable sample to amplify DNA in the sample, a very high positive charge density may be placed on a pin 14 of the pinned lid 10 by contacting the upper end 16 of the pin 14 with a source of positive electrical charge 34. The surface of the lower end 18 of the pin 14 also acquires a very high positive charge. Anions (including the nucleic acids to be “purified”) rapidly bind to the surface of the pin 14. The charge density applied to the pin 14 then is decreased until molecules of only the desired charge (size) remain bound to the pin 14. The pinned lid 10 then is removed from the well plate 2, which removes the pin 14 from the liquid sample 4. The pinned lid 10 is placed on a second well plate 2, which immerses the bottom end 18 of the pin 14 into a second solution. The electrical charge on the pin 14 then is reversed such that the pin 14 becomes an anode containing a net negative charge. The negative charge on the pin 14 repels the negatively charged nucleic acid, and the nucleic acid is released and driven into the second solution and isolated from the reaction products.
As an alternative, when the pin 14 is placed into the second solution, the net positive surface charge may be decreased and not eliminated entirely. This decrease in the charge density of the pin 14 causes smaller nucleic acid fragments to be eluted from the pin 14. By gradually changing the surface charge, a serial purification of nucleic acid fragments based on their relative charge density (size) may be achieved.
The very high net negative charge of DNA amplified by the PCR reaction allows the DNA to be segregated and separated from the unused reactants, other products, and oligonucleotides in a single step. This technique also is used for the purification of proteins, DNA, RNA, or other molecules from 96, 384, 1536, or other well plate 2 formats. The net positive charge on the pin 14 can be precisely regulated by the user to control the binding of anions to the surface of the pin 14. Unlike conventional ion exchange resins that have a fixed net surface charge, the net surface charge on the pin 14 can be selected by the user. At a very high surface density of positive charge, many different anions will bind to the pin 14. As the surface density of positive charge is decreased, the more weakly bound anions will be released into solution. By varying the net surface density of positive charge, purification of the nucleic acid can be achieved. Very precise control of the surface charge will allow separation of nucleic acids that vary only slightly in their net charge (size).
C. Improved Charge Segregation of the Present Invention.
The improvement of the present Invention relates to electrical charge segregation. As illustrated schematically by
The first and second electrical potentials may be supplied by a conventional power supply 34 or source of electrostatic charge. The difference between the first and second electrical potentials defines a voltage between the first and second electrodes 40, 42. The voltage creates a small flow of electrical current between the first and second electrodes 40, 42 and generates an electrical field in the vicinity of the first and second electrodes 40, 42. The first and second electrical potentials are selected to appropriately attract or repel ions in the liquid sample 4, as desired.
If, for example, a positive electrical potential is applied to the first electrode 40, the first electrode 40 is an anode and a positive electrical charge is exhibited to the liquid sample 4 by the first electrode (anode) surface 44. The first electrode 40 will attract negatively charged ions (anions) 48 in the liquid sample 4, such as ions of amplified DNA. The anions 48 of DNA will bind to the first electrode 40. If a negative electrical potential is applied to the second electrode 42, the second electrode 42 is a cathode and a negative electrical charge is exhibited to the liquid sample 4 by the second electrode (cathode) surface 46. The second electrode 42 will attract positively charged ions (cations) 50 in the liquid sample 4, such as ions of the undesirable byproducts of the DNA amplification process. The cations 50 will bind to the second electrode 42.
A pre-selected voltage is applied to the first and second electrodes 40, 42 for a predetermined period of time, effecting electrical charge segregation. The voltage applied between the first and the second electrode 40, 42 will determine the rate at which ions migrate to their respective electrodes. Voltages from 0.001 to 1000 volts can be applied. The preferred voltage is in the range of 1-20 volts DC as this allows for purification of the desired DNA in solution within a reasonable period of time.
In the example shown by
The efficacy of the use of two electrodes 40, 42 for electrical charge segregation has been verified by experiment. In the experiment, both the anode 40 and cathode 42 in a well 6 of a well plate 2 were pins 14. Samples of DNA anions 48 were exposed to DC voltage differences between the cathode 42 and anode 40 ranging from 0.5 volts to 4.7 volts over a period of 20 minutes. At the end of 20 minutes, each anode 40 was placed in a second well 6 of a well plate 2 and allowed to incubate for 5 minutes. Gel electrophoresis was performed on each resulting second liquid sample 4 from the second well plate 2 and compared to electrophoresis of a control and to molecular weight standards. The gel electrophoresis revealed that purification of the DNA was completed in the liquid samples 4 exposed to 3.5 volts or greater for a period of 20 minutes.
As shown by
The pin 14 may be composed of a conductive metal, plastic, carbon or any other conductive material. The conductive material may be applied, deposited or formed as a film, coating or other element to an otherwise non-conductive pin 14; alternatively, the conductive material may have any other configuration adequate to transmit a sufficient electrical charge from the upper end to the lower end of the pin. As used in this application, the term “coating” means any thin layer of material.
Many configurations are suitable for the second electrode 42. Several of those configurations are illustrated by
As shown by
As shown by
The second electrode 42 may be a conducting material incorporated into the structure of the well plate 2, as shown by
As illustrated in
The pinned lid 10 of the present Invention may be utilized for the functions of thermal cycling and sonication in addition to electrical charge segregation, as described in U.S. patent application Ser. No. 10/041,703 filed Jan. 8, 2002 and U.S. patent application Ser. No. 10/356,687 filed Jan. 31, 2003, both of which are incorporated by reference as if set forth in full herein. To effect thermal cycling and as shown by
As shown by
Although this invention has been described and illustrated by reference to specific embodiments, it will be apparent to those skilled in the art that various changes and modifications may be made which clearly fall within the scope of this invention. The present invention is intended to be protected broadly within the spirit and scope of the appended claims.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US1006767||Jan 19, 1910||Oct 24, 1911||Electric hair-drier.|
|US1456005||Jul 24, 1922||May 22, 1923||Jack Harris||Incubator|
|US2379474||Nov 10, 1943||Jul 3, 1945||Bramson Maurice||Heating cabinet, incubator, and the like|
|US3379118||Mar 28, 1966||Apr 23, 1968||Perez William||Baking rack|
|US3616264||Jun 30, 1969||Oct 26, 1971||Beckman Instruments Inc||Temperature-controlled discrete sample analyzer|
|US4038055||Oct 10, 1975||Jul 26, 1977||Block Engineering, Inc.||Gas chromatograph for continuous operation with infrared spectrometer|
|US4116777||Dec 6, 1976||Sep 26, 1978||Labor Muszeripari Muvek||Apparatus for and a method of the determination of influenza neuraminidase|
|US4286456||Aug 9, 1979||Sep 1, 1981||Carlo Erba Strumentazione S.P.A.||Gas chromatographic chamber|
|US4420679||Feb 26, 1982||Dec 13, 1983||Delta Associates, Inc.||Gas chromatographic oven using symmetrical flow of preheated - premixed ambient air|
|US4468423||Nov 17, 1982||Aug 28, 1984||Arlie Hall||Insulating cell element and structures composed thereof|
|US4481405||Apr 27, 1983||Nov 6, 1984||Malick Franklin S||Cooking appliance|
|US4683195||Feb 7, 1986||Jul 28, 1987||Cetus Corporation||Process for amplifying, detecting, and/or-cloning nucleic acid sequences|
|US4683202||Oct 25, 1985||Nov 27, 1990||Cetus Corp||Title not available|
|US4701415||Mar 2, 1984||Oct 20, 1987||Mallinckrodt, Inc.||Controlled atmosphere enclosure|
|US4865986||Oct 6, 1988||Sep 12, 1989||Coy Corporation||Temperature control apparatus|
|US4889818||Jun 17, 1987||Dec 26, 1989||Cetus Corporation||Purified thermostable enzyme|
|US4902624||Nov 21, 1988||Feb 20, 1990||Eastman Kodak Company||Temperature cycling cuvette|
|US4965188||Jun 17, 1987||Oct 23, 1990||Cetus Corporation||Process for amplifying, detecting, and/or cloning nucleic acid sequences using a thermostable enzyme|
|US4981801||May 15, 1985||Jan 1, 1991||University Of Tokyo||Automatic cycling reaction apparatus and automatic analyzing apparatus using the same|
|US5038852||Mar 14, 1990||Aug 13, 1991||Cetus Corporation||Apparatus and method for performing automated amplification of nucleic acid sequences and assays using heating and cooling steps|
|US5061630||May 12, 1989||Oct 29, 1991||Agrogen Foundation, Seyffer & Co. & Ulrich C. Knopf||Laboratory apparatus for optional temperature-controlled heating and cooling|
|US5236666||Feb 11, 1992||Aug 17, 1993||Akzo N.V.||Temperature regulation in a sample handling system for an optical monitoring system|
|US5333675||Feb 22, 1993||Aug 2, 1994||Hoffmann-La Roche Inc.||Apparatus and method for performing automated amplification of nucleic acid sequences and assays using heating and cooling steps|
|US5432086||Dec 16, 1993||Jul 11, 1995||Sy-Lab Vertriebsgellschaft M.B.H.||Apparatus for the automatic monitoring of microorganism culture|
|US5455175||Jan 10, 1994||Oct 3, 1995||University Of Utah Research Foundation||Rapid thermal cycling device|
|US5489532||Feb 28, 1994||Feb 6, 1996||Charm Sciences, Inc.||Automatic test apparatus for antimicrobial drugs|
|US5525300||Oct 20, 1993||Jun 11, 1996||Stratagene||Thermal cycler including a temperature gradient block|
|US5601141||Oct 13, 1992||Feb 11, 1997||Intelligent Automation Systems, Inc.||High throughput thermal cycler|
|US5602756||Dec 8, 1995||Feb 11, 1997||The Perkin-Elmer Corporation||Thermal cycler for automatic performance of the polymerase chain reaction with close temperature control|
|US5604130||May 31, 1995||Feb 18, 1997||Chiron Corporation||Releasable multiwell plate cover|
|US5681492||Feb 16, 1996||Oct 28, 1997||Van Praet; Peter||Incubator for micro titer plates|
|US5716842||Sep 12, 1995||Feb 10, 1998||Biometra Biomedizinische Analytik Gmbh||Miniaturized flow thermocycler|
|US5721136||Nov 9, 1994||Feb 24, 1998||Mj Research, Inc.||Sealing device for thermal cycling vessels|
|US5819842||Aug 18, 1995||Oct 13, 1998||Potter; Derek Henry||Method and apparatus for temperature control of multiple samples|
|US5863507||Nov 7, 1996||Jan 26, 1999||James; Lizymol||Benchtop cooler|
|US5939312||May 17, 1996||Aug 17, 1999||Biometra Biomedizinische Analytik Gmbh||Miniaturized multi-chamber thermocycler|
|US6153426||Dec 20, 1999||Nov 28, 2000||Mwg Biotech Ag||Thermocycler apparatus|
|US6171850||Mar 8, 1999||Jan 9, 2001||Caliper Technologies Corp.||Integrated devices and systems for performing temperature controlled reactions and analyses|
|US6197575||Mar 18, 1999||Mar 6, 2001||Massachusetts Institute Of Technology||Vascularized perfused microtissue/micro-organ arrays|
|US6312960||Dec 22, 1998||Nov 6, 2001||Genometrix Genomics, Inc.||Methods for fabricating an array for use in multiplexed biochemical analysis|
|US6331441||Dec 21, 1998||Dec 18, 2001||Genometrix Genomics Incorporated||Multiplexed molecular analysis apparatus and method|
|US6338802||May 4, 2000||Jan 15, 2002||Pe Corporation (Ny)||Multi-well microfiltration apparatus|
|US6372486||Nov 29, 1999||Apr 16, 2002||Hybaid Limited||Thermo cycler|
|US6423536||May 23, 2000||Jul 23, 2002||Molecular Dynamics, Inc.||Low volume chemical and biochemical reaction system|
|US6451261||May 4, 2000||Sep 17, 2002||Applera Corporation||Multi-well microfiltration apparatus|
|US6479301||Oct 2, 2000||Nov 12, 2002||Genometrix Genomics Incorporated||Methods for fabricating an array for use in multiplexed biochemical analysis|
|US6489112||Aug 2, 2000||Dec 3, 2002||Molecular Dynamics, Inc.||Methods and apparatus for template capture and normalization for submicroliter reaction|
|US6627421||Apr 5, 2001||Sep 30, 2003||Imarx Therapeutics, Inc.||Methods and systems for applying multi-mode energy to biological samples|
|US6948843||Mar 20, 2001||Sep 27, 2005||Covaris, Inc.||Method and apparatus for acoustically controlling liquid solutions in microfluidic devices|
|1||Cao, T., "A Simple and Inexpensive System to Amplify DNA by PCR," Biotechniques, 7(6):566-7, Jun. 1989.|
|2||Chapin, K., et al., "Evaluation of a Rapid Air Thermal Cycler for Detection of Mycobacterium tuberculosis," J Clin Microbiol., 35(8):2157-9, Aug. 1997.|
|3||Civitello, A., et al., "A Simple Protocol for the Automation of DNA Cycle Sequencing Reactions and Polymerase Chain Reactions," DNA Seq., 3(1):17-23, 1992.|
|4||Constans, A., "Some Like it Hot: A Thermal Cycler Roundup," The Scientist, 15(24):32, Dec. 10, 2001.|
|5||Denton et al., PCR Protocols: A Guide to Methods and Applications, "A Low-Cost Air-Driven Cycling Oven," pp. 435-441, 1990.|
|6||Mai, M., et al., "Shortened PCR Cycles in a Conventional Thermal Cycler," Biotechniques, 25(2):208-10, Aug. 1998.|
|7||Merriam-Webster's Collegiate Dictionary, Tenth Edition, Merriam Webster Incorporated, 1996, p. 959.|
|8||Perry and Green, Perry's Chemical Engineer's Handbook, 7th ed., "Heat Transfer by Radiation," pp. 5-23 to 5-42, 1997.|
|9||Soper, S., et al., "Sanger DNA-sequencing Reactions Performed in a Solid-phase Nanoreactor Directly Coupled to Capillary Gel Electrophoresis," Anal Chem., 70(19):4036-43, Oct. 1, 1998.|
|10||Tret'iakov, A., et al., "Fast DNA Amplification in Small Ultrathin-wall Microplates," Bioorg Khim., 23(6):526-8, Jun. 1997.|
|11||Weis, J., et al., "Detection of Rare mRNAs via Quantitative RT-PCR," Trends Genet., 8(8):263-4, Aug. 1992.|
|12||Wilding, P., et al., "PCR in a silicon microstructure," Clin Chem., 40(9):1815-8, Sep. 1994.|
|13||Wittwer, C., et al., "Minimizing the Time Required for DNA Amplification by Efficient Heat Transfer to Small Samples," Anal Biochem., 186(2):328-31, May 1, 1990.|
|14||Wittwer, C., et al., "Rapid Cycle DNA Amplification: Time and Temperature Optimization.," Biotechniques, 10(1):76-83, Jan. 1991.|
|U.S. Classification||165/269, 435/287.2, 422/520|
|International Classification||F25B29/00, G05D23/19, C25D17/06|
|Cooperative Classification||B01L2300/1827, B01L2400/0415, B01L7/52, B01L2200/0631, B01L2300/0829|
|Feb 15, 2013||FPAY||Fee payment|
Year of fee payment: 4
|Jul 25, 2013||AS||Assignment|
Effective date: 20130724
Owner name: MATRICAL, INC., WASHINGTON
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:OLDENBURG, KEVIN;REEL/FRAME:030873/0405
|Dec 31, 2013||AS||Assignment|
Owner name: BROOKS AUTOMATION, INC., MASSACHUSETTS
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:MATRICAL, INC.;REEL/FRAME:031864/0237
Effective date: 20130801